Monitoring Hong Kong’s Bridges Real-Time Kinematic Spans the Gap by Kai-yuen Wong, King-leung Man, and Wai-yee Chan Modern cable-supported bridges carry ong Kong’s Tsing Ma Bridge is the world’s longest Hspan suspension bridge carrying both road and enormous loads across great distances, in rail traffic. As with other long-span cable-supported part due to their designed capability to bridges, it can move from several centimeters to sever- move, ever so slightly, under varied al meters under different types of loading conditions. Although these displacements or deformations may conditions. In Hong Kong, a real-time not create hazardous conditions for traffic actually on kinematic (RTK) GPS monitoring system the bridge, as they increase in size, they significantly provides the centimeter-level accuracy, in affect the bridge’s structural integrity and maintenance needs. Real-time measurement accuracy of GPS has all weather conditions, to detect bridge improved to centimeter-level precision recently, making movements beyond normal ranges. it well-suited to monitor variations in three-dimension- Engineers can then conduct inspections al bridge motion in response to wind, temperature, and traffic loads. This article describes the layout and tech- or maintenance needed to maintain nical performance requirements of such a system and longterm structural health. discusses the results in bridge structural health moni- toring. Kai-yuen Wong (Eur Ing, chartered engineer) The Highways Department of Hong Kong Special is senior engineer in the Bridge Health Section of Tsing Administrative Region designed the Wind and Ma Control Area Division, Highways Department, Structural Health Monitoring System (WASHMS) for Hong Kong Special Administrative Region. three large cable-supported bridges, Tsing Ma Bridge, King-leung Man and Wai-yee Chan (Ir, chartered Kap Shui Mun Bridge, and Ting Kau Bridge, in the Tsing engineers) are engineers in the Ma Control Area (TMCA) of western Hong Kong. Tsing same Bridge Health Section. Ma Bridge measures 1,377 meters across the Ma Wan shipping channel. Built at a cost of approximately HK$7.2 billion (US$925 million), the suspension bridge provides high-speed rail and road connections to Hong Kong’s busy international airport. Ting Kau and Kap Shui Mun bridges, 1177 and 820 meters long, respec- tively, use cable-stayed construction. We saw an opportunity to improve the efficiency and accuracy of the existing monitoring system with GPS technology, to monitor the displacements of the main suspension cables, decks, and bridge towers. We use these measured displacement values to derive the rele- vant stress status acting on major bridge components. Displacement of bridge structure serves as an effec- tive indicator of its structural performance condition. We are establishing Finite Element Models (FEM) with geometrical configurations will redistribute stresses The three bridges reference to GPS measurement for the three bridges; and strains among bridge components, affecting the and major high- these models will enable us to identify critical structur- load-carrying capacity of the whole bridge. ways of western al components, for the purpose of long-term inspection Until recently, the WASHMS for Tsing Ma Bridge Hong Kong’s Tsing and maintenance. (TMB), Kap Shui Mun Bridge (KSMB) and Ting Kau Ma Control Area. The real-time GPS On-Structure Instrumentation Bridge (TKB) consisted of 774 sensors in seven major System (GPS-OSIS) constitutes five sub-systems: the types: anemometers, temperature sensors, dynamic GPS receivers themselves, local and global data acqui- weigh-in-motion sensors, accelerometers, displacement sition systems, a computer system, and a fiberoptic net- transducers, level sensing stations, and strain gauges. work. GPS-OSIS improves the efficiency and accuracy The commissioning of GPS-OSIS in January, 2001, of WASHMS monitoring and evaluation activities by: brought an additional 29 sensors into the overall sys- reporting displacements, reflecting loading and tem. Now fully operational, GPS-OSIS functions as an stress conditions additional system integral to the existing WASHMS for providing more information to estimate distribu- improving the efficiency and accuracy of bridge health tion of stresses/strains in major bridge components monitoring works. documenting abnormal loading incidents such as Although the annual TMCA geodetic survey mea- typhoons, earthquakes, traffic overloads, and ship colli- sures the geometrical configurations of the three sions with bridge piers bridges, this serves for monitoring geometrical varia- detecting damage or accumulated damage in tions due to permanent and long-term structural major bridge components actions such as dead loads and super-imposed dead estimating bridge load-carrying capacities and val- loads. Geodetic surveying cannot detect the bridges’ idating design assumptions and parameters instant responses to transient and variable structural providing information for planning and schedul- actions such as primary live loads. Before GPS deploy- ing bridge inspection and maintenance activities. ment, accelerometers monitored geometrical varia- tions, but this method, due to uncertainties or unknown Overview integration constants, only provides relative local dis- Structural design of cable-supported bridges is based placements at measurement locations, and does not on displacements. Displacements or movements of give overall absolute displacements. cables, decks, and towers that deviate from the design’s This difference becomes very important in the case, Receiver atop Tsing Bridge Acronyms Ma Bridge tower, GPS-OSIS GPS On-Structure with Kap Shui Mun Bridge in the Instrumentation System distance HKSAR Hong Kong Special Administrative Region HyD Highways Department KSMB Kap Shui Mun Bridge LFC-OSIS Lantau Fixed Crossing — On-Structure Instrumentation System TKB Ting Kau Bridge TMB Tsing Ma Bridge TMCA Tsing Ma Control Area WASHMS Wind and Structural Health Monitoring System zontally, the Highways Department (HyD) of Hong Kong Special Administrative Region (HKSAR) re-inves- tigated GPS use for monitoring the bridges’geometrical configurations. The reported suitability of GPS as an all-weather system also became an important factor in its adoption. This has yet to be fully demonstrated, although the impending typhoon seasons should put it to the test. The Case for GPS-OSIS In the past, level sensing stations and servo-type accelerometers monitored bridge responses in TMCA. The level sensing stations, at a sampling rate of 2.56 Hz, provide real-time monitoring of displacements, with a measurement accuracy of approximately 2 millimeters at typical deck sections at vertical planes only. These FIGURE 1 GPS-OSIS for example, of a strong wind swaying the bridge deck level sensing stations are used only on the TMB and structure alignment steadily to one side, or daily temperature KSMB, but not on TKB because the installation cost of variation raising or lowering bridge deck level, and sus- pipeline systems along the bridge would be high (a taining these changes over a period of time before level-sensing system measures pressure changes in sen- returning to normal position. Accelerometers cannot sors installed along a network of flexible hoses). detect such continuous or steady displacement of the However, they cannot measure the lateral and longitu- massive deck, only instant local vibration, and they do dinal displacements of the deck sections in the horizon- not give an overall true or absolute displacement. Their tal plane. limitation in detecting slow global displacement would High precision servo-type accelerometers monitor introduce error in mathematical derivations. the local vertical, lateral and rotational accelerations of History. During the initial WASHMS design stage in the decks, cables and bridge-towers of TMB, KSMB and 1992, we considered other measuring technologies TKB. Displacement monitoring requires double-integra- such as infrared and laser for displacement monitoring. tion of the measured acceleration data to determine As these required visibility over a definite distance and the three-dimensional motions of the three cable-sup- could not operate fully under severe weather condi- ported bridges. Because the natural frequencies of the tions, we dropped them from consideration. We also decks are of very low values, double-integration of considered and then dropped GPS, due to its less than their acceleration data cannot reflect actual displace- requisite accuracy at that time. ment values. FIGURE 2 Location of As real-time accuracy of post-Selective Availability After trial tests on TMB in 1999 and 2000 demonstrat- GPS rover receivers GPS for survey application has improved to approxi- ed GPS applicability and the required accuracy level, on Tsing Ma Bridge mately 20 millimeters vertically and 10 millimeters hori- HyD decided to employ GPS with Real Time Kinematic (RTK) function to monitor displacements of the three cable-supported bridges. GPS-OSIS monitors real-time motions of the main suspension cables, decks, and bridge towers of TMB, KSMB, and TKB, derives the rele- vant stress status acting on the major bridge compo- nents, and works with other WASHMS instrumentation systems to monitor overall bridge health and schedule inspections and maintenance activities. System Description Figure 1 shows the five major system components. The GPS sensory system consists of two base reference sta- FIGURE 3 Location of GPS rover receivers on Kap Shui
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